TWM502987U - Electrical connector including fins - Google Patents

Abstract

An electrical connector can be configured to mate with at least one complementary electrical connector. The electrical connector includes a dielectric connector housing including a housing body that defines a mounting interface configured to be mounted onto a substrate and a mating interface configured to receive at least one complementary electrical connector along a mating direction. A plurality of electrical contacts are supported by the connector housing and spaced apart from each other along a lateral direction that is substantially perpendicular to the mating direction. The electrical contacts include 1) a mating portion that is configured to mate with a complementary electrical contact of the complementary electrical connector, and 2) a mounting portion configured to electrically connect to the substrate. The electrical connector can further include at least one electrically insulative fin supported by the housing body.

Description

Electrical connector including fins

An electrical connector for transmitting data signals and/or power, such as alternating current (AC) power and/or direct current (DC) power, can include a plurality of power contacts and a plurality of signal contacts mounted in an electrically insulative housing . In a typical application, the connector can be configured to be mounted to a substrate (such as a printed circuit board) and configured to mating with a complementary electrical component (for example, it can be a power cable or complementary power) Connector). In particular, each of the contacts within the housing may include one or more plug and/or socket contacts respectively mating with opposing sockets and/or plug contacts of the complementary electrical component.

A typical contact includes a plurality of terminals or pins extending from a bottom for electrically connecting the contacts to a substrate, such as a printed circuit board. In the case of a power contact, the high voltage level traveling through the terminal can create an arc across the terminal, which can also be referred to as leakage or creep. Therefore, it is known that under other constant conditions (for example, the same substrate material and the number of terminals), separating the terminals from each other can reduce the arc. However, separating the terminals far apart while maintaining the number of terminals increases the total footprint of the connector, thereby occupying valuable space on the board.

According to an embodiment, an electrical connector is configured to mate with at least one complementary electrical connector. The electrical connector includes a dielectric connector housing including a housing body defining a mounting interface configured to be mounted to a substrate and configured to be mated along a mating One of the mating interfaces is mated with at least one complementary electrical connector. A plurality of electrical contacts are supported by the connector housing and are substantially perpendicular to the mating direction One of the lateral directions is spaced apart from each other. The electrical contacts comprise: 1) a mating portion configured to mate with a complementary electrical contact of the complementary electrical connector; and 2) a mounting portion configured to electrically connect to the Substrate. The electrical connector can further include at least one electrically insulating fin supported by the housing body. The fins may be disposed between the first electrical contact and the second electrical contact of the plurality of electrical contacts along the lateral direction. The mounting portion of each of the first electrical contact and the second electrical contact may terminate at a mounting end along a lateral direction perpendicular to the mating direction and the lateral direction The housing bodies are spaced apart by a first distance. The at least one fin may extend from the housing body along the lateral direction and may terminate at a distal end spaced apart from the housing body by a second distance along the lateral direction, wherein the second distance is not less than the first distance.

99‧‧‧Electrical connector system

100‧‧‧Electrical connector assembly/first electric assembly

102‧‧‧First electrical connector

102a‧‧‧Electrical connector

102b‧‧‧Neutral electrical connector

104‧‧‧First substrate/substrate

106‧‧‧First dielectric or electrically insulated connector housing/electric housing

106b‧‧‧ Shell

107‧‧‧ inner surface

108‧‧‧Electrical contacts

108a‧‧‧Signal contacts

108b‧‧‧Electrical contacts

109a‧‧‧Socket electrical contacts

109b‧‧‧ plug electrical contacts

110‧‧‧First shell body

110a‧‧‧ front end

110b‧‧‧ backend

110c‧‧‧Top

110d‧‧‧ bottom

110e‧‧‧ first opposite side

110f‧‧‧ second opposite side

112‧‧‧First mating interface

114‧‧‧First installation interface

116‧‧‧Socket opening

118‧‧‧Matching part

120‧‧‧Installation section

122‧‧‧ middle part

124‧‧‧Installation terminal

124a‧‧‧First mounting terminal

124b‧‧‧Second mounting terminal

125‧‧‧Installation terminal pair

126‧‧‧ plated through hole

128‧‧‧Installation location

128’‧‧‧Installation location

128"‧‧‧Installation location

130‧‧‧ occupied area

132‧‧‧ Adapter

134‧‧‧Installation end

136‧‧‧First side wall

138‧‧‧ second side wall

140a‧‧‧First neck

140b‧‧‧second neck

142‧‧‧First bridging element

144‧‧‧Second bridging element

146‧‧‧Intermediate space

148‧‧‧ slot

150a‧‧‧first insulating arm / first arm

150b‧‧‧Second insulation arm / second arm

151a‧‧‧first barb

151b‧‧‧second barb

152‧‧‧ position

153a‧‧‧First arm body

153b‧‧‧second arm body

154‧‧‧ position

156‧‧‧Electrically insulated fins

157‧‧‧Remote

160‧‧‧ gap

200‧‧‧Second or complementary electrical connector assembly/complementary electrical assembly

202‧‧‧Second or complementary electrical connector

206‧‧‧Second or complementary dielectric or electrically insulated connector housing

208‧‧‧Complementary electrical contacts

212‧‧‧Second or complementary mating interface

214‧‧‧Second or complementary installation interface

222‧‧‧ wall

C ₁ ‧‧‧ first line

C ₂ ‧‧‧ second line

R ₁ ‧‧‧first column

R ₂ ‧‧‧Second column

R ₃ ‧‧‧ third column

R ₄ ‧‧‧fourth column

W ₁ ‧‧‧Fin width

CD‧‧‧ creepage distance

CP‧‧‧ line spacing

1A is a perspective view of an electrical connector system including an electrical connector assembly (which includes an electrical connector mounted to an underlying substrate) constructed in accordance with an embodiment, wherein the electrical connector assembly is paired 1B is another perspective view of the electrical connector system shown in FIG. 1A; FIG. 2A is a perspective view of the electrical connector assembly shown in FIG. 1A, wherein the electrical The connector includes a connector housing and a plurality of electrical contacts at least partially disposed within the connector housing; Figures 2B-2C are other perspective views of the electrical connector assembly shown in Figure 1A; Figure 2D is in Figure 1A A rear view of one of the electrical connector assemblies shown; FIG. 3A is an isolated rear view of one of the electrical contacts of the plurality of electrical contacts shown in FIG. 2A; FIG. 3B is another of the electrical contacts shown in FIG. 3A Figure 3C is a perspective view of one of the electrical contacts shown in Figure 3A; Figures 4A-4B are perspective views of the electrical connector shown in Figure 2A, wherein the electrical connector is aligned Mounted to the underlying substrate; Figure 5 is a bottom plan view of one of the portions of the underlying substrate shown in Figure 2A; Figure 6 is a bottom plan view of a portion of the underlying substrate shown in Figure 2A, wherein only the connector housing of Figure 2A is mounted to the substrate; Figure 7A is a cross-sectional view of one of the perspective views of the electrical connector system shown in Figure 1A, Wherein the electrical connector assembly is mated with a complementary electrical connector; Figure 7B is an isolated view of one of the portions of Figure 7A; Figure 8A is aligned for mating with the complementary electrical connector shown in Figure 1A, shown in Figure 1A One of the electrical connectors is a cross-section of a top plan view; FIG. 8B is a cross-sectional view of one of the top views of the electrical connector shown in FIG. 1A mated with the complementary electrical connector shown in FIG. 1A; FIG. A perspective view of another embodiment of the electrical connector shown in FIG. 2A including a signal contact; FIG. 10A is a perspective view of one of the neutral electrical connectors constructed in accordance with yet another embodiment; and FIG. 10B is associated with A bottom plan view of the neutral electrical connector shown in Figure 10A of a complementary neutral electrical connector mating.

For the sake of convenience, the same or equivalent elements of the various embodiments shown in the drawings have been identified with the same reference numerals. The specific terminology is used in the following description for convenience only and is not a limitation. The words "left", "right", "front", "back", "up" and "down" specify the direction in the referenced drawing. Words "forward", "forward", "forward", "internal", "inward", "inward", "outside", "outward", "outward", "upward", " Upward, downward, and downward are directions toward and away from the geometric center of the object being referenced and its designated portion, respectively. Terms intended to be non-limiting include the words listed above, derivatives thereof, and the like.

Referring first to FIGS. 1A-1B, an electrical connector system 99 can include a first electrical connector assembly 100 and a second or complementary electrical connector assembly 200, in accordance with an embodiment. Electrical connection The assembly 100 can include a first electrical connector 102 and a first electrical component such as a first substrate 104, and the complementary electrical connector assembly 200 can include a second or complementary electrical connector 202 and such as a A second electrical component of one of the complementary substrates. The electrical connectors 102 and 202 can be configured to mate with each other to establish an electrical connection, for example, between the electrical connectors 102 and 202, and thus between the first electrical assembly 100 and the complementary electrical assembly 200, respectively. One of the electrical connections is electrically connected. The electrical connector 102 can be configured to be mounted to the substrate 104 and the complementary electrical connector 202 can be configured to be mounted to a complementary substrate to establish an electrical connection between the substrates. The substrates can be provided as a backing, midplane, daughterboard or the like.

Referring also to FIGS. 2A-2D, the electrical connector 102 includes a first dielectric or electrically insulative connector housing 106 and at least one (eg, a plurality of) electrical contacts 108 disposed at least partially within the connector housing 106. Electrical contacts 108 can include power contacts configured to transmit current. Electrical contacts 108 can include signal contacts configured to transmit data. In accordance with the illustrated embodiment, when the electrical connector 102 is mounted to the substrate 104 along a mounting direction, the electrical contacts 108 are placed in electrical communication with the electrical traces of the substrate 104. The complementary electrical connector 202 can include a second or complementary dielectric or electrically insulative connector housing 206 and at least one (such as a plurality of) complementary electrical contacts 208 supported by the complementary connector housing 206. When the electrical connector 202 is mounted to the complementary substrate, the electrical contacts 208 are placed in electrical communication with the electrical traces of the complementary substrate. The electrical connector 102 can be configured to mate with the complementary electrical connector 202 along a mating direction M for respectively between the first electrical contact 108 and the second electrical contact 208 and thus also on the substrate 104 An electrical connection is established between the electrical traces of the complementary substrate. The plurality of electrical contacts 108 can be supported by the connector housing 106 and spaced apart from one another in a lateral direction A that is substantially perpendicular to the mating direction M.

Referring also to FIGS. 3A-4B, in accordance with the illustrated embodiment, the electrical connector 102 can be constructed as a right angle receptacle connector that includes the connector housing 106. The connector housing 106 includes a first housing body 110 that defines a first mating interface 112 and a first mounting interface 114 that are oriented substantially perpendicularly relative to one another to define a right angle receptacle connector 102. It should be understood that the electrical connector 102 can be constructed as desired, for example, as a vertical connector. The mating interface 112 is made parallel with respect to the mounting interface 114. The mounting interface 114 can be configured to be mounted to a substrate and the mating interface 112 can be configured to mate with at least one complementary electrical connector along the mating direction M.

In accordance with the illustrated embodiment, the complementary electrical connector 202 can be constructed as a right angle plug connector that defines a second or complementary mating interface 212 and a second or complementary mounting that extends substantially perpendicular to the complementary mating interface 212 Interface 214. The mating interface 112 of the electrical connector 102 can be configured to mate with a complementary mating interface 212 of the complementary electrical connector 202. The first mounting interface 114 and the complementary mounting interface 214 can each be configured to be mounted to an underlying substrate, such as the substrate 104 and the complementary substrate. The mating interface 112 of the electrical connector 102 can include a receptacle opening 116 defined by the connector housing 106 such that when the electrical connector 102 mates with the complementary electrical connector 202, the complementary electrical contacts 208 of the complementary electrical connector 202 It can be received in the socket opening 116.

As shown in the illustrated embodiment, the electrical connector 102 can be configured as a receptacle connector and the complementary electrical connector 202 can be configured as a plug connector such that the connector housing 106 is configured to receive a complementary connector The outer casing 206 is to mate the first electrical connector 102 with the complementary electrical connector 202.

Various structures are described herein as extending horizontally along a first or longitudinal direction "L" and substantially perpendicular to the longitudinal direction L, a second or lateral direction "A", and substantially perpendicular to the longitudinal direction, respectively. One of the direction L and the lateral direction A or the lateral direction "T" extends vertically. As shown, the longitudinal direction "L" extends in a forward/backward direction of one of the electrical connectors 102 and defines a mating direction M, one or both of the electrical connector 102 and the complementary electrical connector 202 are mated The directions M are moved relative to each other to mate the electrical connector assembly 100 with the complementary electrical connector assembly 200 and thus the electrical connector 102 mated with the complementary electrical connector 202. For example, the mating direction M of the electrical connector 102 is shown in a forward direction along the longitudinal direction L, and can be made relative to the complementary electrical connector 202 by the electrical connector 102 in an opposite longitudinally rearward direction. Moving moves the electrical connector 102 out of mating with the complementary electrical connector 202. As illustrated, the electrical connector 102 can be oriented along a lateral direction defining the mounting direction The direction T is moved relative to the substrate 104, and the lateral direction "A" extends along one of the widths of the electrical connector 102.

Therefore, the terms "lateral", "longitudinal" and "lateral" are used to describe the orthogonal direction components of the various components, unless otherwise specified herein. The terms "inside" and "inside" and "outside" and "outside" and the like, when used in relation to a particular directional component, are intended to mean a direction along the direction of the component toward and away from the center of the device being described. It will be appreciated that while the longitudinal and lateral directions are depicted as extending along a horizontal plane and the lateral direction is depicted as extending along a vertical plane, such planes encompassing various directions may be used, for example, depending on The orientation of the various components varies. Accordingly, the directional terms "vertical" and "horizontal" are used for the purpose of clarity and convenience for describing the electrical connector assembly 100 and its components as illustrated, and it will be appreciated that such orientations may vary in use.

With continued reference to FIGS. 1 through 4B, in accordance with the illustrated embodiment, the housing body 110, and thus the connector housing 106, defines a front end 110a and one of the opposite ends 110b spaced from the front end 110a along the longitudinal direction L. The front end 110a can be located generally in one of the planes defined by the lateral direction T and the lateral direction A, respectively. The front end 110a can define a mating interface 112 that is configured to mate with the complementary electrical connector 202 to place the electrical connector 102 in electrical communication with the complementary electrical connector 202. The housing body 110 and thus the connector housing 106 can further include a top end 110c and one of the spaced apart end ends 110d from the top end 110c along the transverse direction T. For example, the tip end 110c can be spaced from the bottom end 110d in an upward direction that is substantially parallel to one of the lateral directions T. Therefore, the bottom end 110d can be spaced apart from the top end 110c in a downward direction substantially parallel to one of the lateral directions T. The top end 110c can extend from the front end 110a to the rear end 110b. The bottom end 110d can define a mounting interface 114 that is configured to be mounted to the substrate 104. The bottom end 110d can be generally located in one of the planes defined by the longitudinal direction L and the lateral direction A, respectively. The connector housing 106 and thus the electrical connector 102 can further include a first opposing side 110e and a second opposing side 110f that are spaced apart from each other along the lateral direction A, respectively. Although oriented according to the electrical connector assembly 100, the lateral direction A and the longitudinal direction L extend horizontally and the transverse direction T is vertical, respectively. Extend, but it should be understood that the orientation of the electrical connector assembly 100 can be varied as desired.

Referring to FIGS. 3A-3C, each of the electrical contacts 108 can define a mating portion 118, a mounting portion 120, and an intermediate portion 122 extending between the mating portion 118 and the mounting portion 120. The mating portion 118 can be configured to mate with a complementary electrical contact 208 of the complementary electrical connector 202 to be mated with the electrical connector 102. Accordingly, the mating portion 118 can be configured to mating with a complementary electrical contact of one of the at least one complementary electrical connector when the connector housing 106 mates with the at least one complementary electrical connector.

Mounting portion 120 can be configured to electrically connect to substrate 104 when connector housing 106 is mounted to substrate 104. The mounting portion 120 can include one or more mounting terminals 124 that are disposed proximate to the mounting interface 114 and that are configured to electrically connect to the substrate 104. In an embodiment, the mounting terminal 124 is inserted through the plated through hole 126 of the substrate 104 and the mounting terminal 124 defines a press-fit tail. The through hole 126 can define a mounting location 128 that defines one of the footprints as described with respect to the footprint 130 described below with respect to Figures 5-6. Alternatively, the mounting terminal 124 can be surface mounted to the substrate 104. Mounting terminal 124 can be further soldered to substrate 104 as desired. Thus, when the complementary electrical connector 202 is mated with the electrical connector assembly 100, the electrical contacts 108 can place the substrate 104 in electrical communication with the complementary electrical connector 202. The electrical contacts 108 can be configured as power contacts that transfer power between the substrate 104 and a complementary electrical component, such as one of the electrical connectors 202. Thus, the electrical connector 102 can be configured as a power connector.

According to the illustrated embodiment, the mating portion 118 extends forwardly from the intermediate portion 122 along the longitudinal direction L and terminates at a mating end 132, and the mounting terminal 124 extends downwardly from the intermediate portion 122 in the lateral direction and terminates At a mounting end 134. The mounting end 134 can be configured to be placed in electrical communication with the substrate 104 when the mounting interface 114 is mounted to the substrate 104. The mating portion 118 is shown extending in a direction substantially perpendicular to one of the mounting terminals 124 such that the electrical contacts 108 can be referred to as right angle contacts. Alternatively, the electrical contacts 108 can be constructed in a "vertical" or "sandwich" configuration whereby the mating portion 118 extends in a direction parallel to one of the mounting terminals 124.

Since the mating end 132 of the electrical contact 108 is configured to receive its complementary contacts 208, it may be referred to as a "socket" contact, and the electrical connector 102 may be referred to as a "socket" connection. Device.

Referring to FIGS. 3A-3C and 7A-8B, each of the electrical contacts 108 includes a first sidewall 136 and a second sidewall 138 spaced along the lateral direction A from the first sidewall 136 to define It is called a distance of one third distance d ₃ . The mounting portion 120 of each electrical contact 108 includes at least a pair 125 of mounting terminals 124. The mounting terminals 124 of each pair 125 are aligned with each other along the longitudinal direction L and are spaced apart from each other along the lateral direction A. The mounting portion 120 further defines at least one neck, such as a first neck extending between the first side wall 136 and the second side wall 138 and between the first plurality of mounting terminals 124a and the second plurality of mounting terminals 124b, respectively. 140a and second neck 140b. Therefore, each pair 125 of mounting terminals 124 includes a first mounting terminal 124a and a second mounting terminal 124b. The first neck portion 140a and the second neck portion 140b may be bent or inclined inward in the downward lateral direction T such that the first mounting terminal 124a and the second mounting terminal 124b of each pair 125 are separated from each other along the lateral direction A. The opening is shorter than the first side wall 136 and the second side wall 138 is spaced apart from each other by a distance in the lateral direction A. For example, the electrical contact 108 can include a first plurality of mounting terminals 124a and a second plurality of mounting terminals 124b that can be spaced apart from each other along the lateral direction A to define a distance less than a third distance d ₃ ( It can be referred to as a fourth distance d ₄ ). The electrical contact 108 can further include a first neck portion 140a extending between the first sidewall 136 and the first plurality of mounting terminals 124a and a second neck extending between the second sidewall 138 and the second plurality of mounting terminals 124b Part 140b.

The mounting terminal 124 can define a through hole, a soldered to board pin (as shown in FIG. 3B), a press fit pin (as shown in FIG. 3C) or a surface mount tail or configured to electrically connect to the substrate 104. A suitable alternative structure. The first sidewall 136 and the second sidewall 138 may be connected by one or more bridging elements (eg, a first bridging element 142 and a second bridging element 144), and thus each of the electrical contacts 108 may be U-shaped, It should be understood, however, that the electrical contacts 108 can alternatively be shaped as desired. Defining, for example, between the first sidewall 136 and the second sidewall 138, respectively The adjustment applies to one of the intermediate spaces 146 of air flow. It should be understood that the electrical contacts 108 may be stamped or otherwise formed as a single piece from one of a suitable contact material such as a phosphor bronze alloy, beryllium copper alloy, or any suitable alternative conductive material.

The housing body 110, and thus the connector housing 106, can define a socket opening 116 that is configured to receive at least one conductive component along a longitudinal direction L (which can be referred to as a mating direction M). The opening 116 can be disposed at the front end 110a. The electrical contacts 108 can be supported by the connector housing 106 and can be configured to contact the complementary electrical contacts 208 when the complementary electrical connector 202 is received in the opening 116. In accordance with the illustrated embodiment, the socket opening 116 is disposed at the front end 110a of the connector housing 106 such that the connector housing front end 110a can define the opening 116. The connector housing can further define a first electrically insulating arm 150a and a second electrically insulating arm 150b that are spaced apart from each other along the lateral direction A and supported by the housing body 110. The first arm 150a and the second arm 150b can abut the first sidewall 136 and the second sidewall 138, respectively, such that the first sidewall 136 and the second sidewall 138 are at least partially disposed within the socket opening 116. Accordingly, the first arm 150a and the second arm 150b can further define the socket opening 116. In particular, the mating portion 118 of each electrical contact 108 can be disposed within the opening 116 such that when the complementary electrical connector 202 is received in the receptacle opening 116, the mating portion 118 contacts the complementary electrical contact 208. The arms 150a and 150b can extend forward from the housing body 110 along the longitudinal direction L. Alternatively, the arms 150a and 150b can be integral with the housing body 110.

The first arm 150a can define a first arm body 153a and a first barb 151a extending from the arm body 153a in the lateral direction A so as to be disposed in front of the mating end 132 along the longitudinal direction L. Similarly, the second arm 150b can define a second arm body 153b and a second barb 153b extending from the arm body 151b in the lateral direction A so as to be disposed in front of the mating end 132 along the longitudinal direction L. Therefore, the barbs 151a and 151b can be disposed at the front end 110a of the connector housing 106, and the barbs 151a and 151b can contact the mating end 132 in the lateral direction A such that the mating end 132 is resistant to contact, and thus blocks The mating end 132 contacts or otherwise prevents humans from touching the mating end 132 with their fingers. As used in this article, anti-touch can also Refers to one of the standard tests published in IEC 60950, which verifies that the contact portion such as the mating end or the mounting end cannot be touched by a test finger. Therefore, the mating end 132 can be touch-proof such that the mating end 132 cannot be touched by a test finger (which represents a human finger) from every reasonable position. Further, at least one arm (eg, the first arm 150a and the second arm 150b) may be supported by the housing body 110. The at least one arm may extend beyond the mating portion 118 in the mating direction M such that the mating portion 118 terminates inward along a mating direction M with respect to a position 154 that terminates in the mating direction M relative to the arm. One location is 152.

Referring specifically to FIGS. 7A-8B, a first arm 150a adjacent one of the first electrical contacts 108 can be spaced apart from the second arm 150b adjacent one of the second electrical contacts 108 in a lateral direction to define a gap 160. . The gap 160 can be configured to receive a portion of the complementary connector housing 206 when the electrical connector 102 mates with the complementary electrical connector 202. For example, the complementary connector housing 206 can define a wall 222 that extends beyond the complementary electrical contact 208 along the mating direction M such that the complementary contacts are resistive, and the wall 222 can be received by the gap 160 such that the electrical connection The complementary electrical contacts 208 can be electrically connected to the electrical contacts 108 when the device 102 is mated with the complementary electrical connector 202. Accordingly, the complementary connector housing 206 can be received into the gap 160 that extends into the housing body 110.

Accordingly, the connector housing 106 can include an inner surface 107 that defines at least one opening 116 such that at least one of the plurality of electrical contacts 108 is disposed in the opening. The inner surface 107 can at least substantially surround at least one of the plurality of electrical contacts 108, and the inner surface 107 can extend from the housing body 110 along the mating direction M beyond at least one of the plurality of electrical contacts 108 The terminal 132, wherein at least one of the electrical contacts terminates at the mating end 132. Thus, the electrical contacts 108 and thus the electrical connector 102 can be protected from contact at the mating end 132. Thus, the connector housing 106 can extend beyond the mating end 132 of the electrical contact 108 along the mating direction M.

Referring specifically to FIGS. 4A-4B, the connector housing 106 and thus the electrical connector 102 can include at least one electrically insulating fin, such as a plurality of electrically insulating fins 156 supported by the housing body 110. It should be understood that the fins 156 can be integral with or attached to the outer casing body as desired. Shell body 110. Each fin 156 can be disposed between the electrical contacts 108 along a lateral direction A. For example, at least one fin 156 can be disposed between at least a first electrical contact and a second electrical contact 108 of the plurality of electrical contacts along a lateral direction A. At least one fin (eg, each fin 156) may extend downward relative to the mounting portion 120 (and in particular the mounting end 134) such that the mounting end 134 is resistive and is mounted to the substrate 104 at the electrical connector 102 The at least one fin 156 is received by the substrate 104 before the mounting portion is received by the substrate 104. Therefore, according to the IEC 60950 test procedure, the electrical contacts 108 can be protected from contact at the mating end 132 and the mounting end 134. The fin 156 can be coupled to the bottom end 110d of the housing body 110. Therefore, the mating end 132 and the mounting end 134 can be prevented from being touched, so that the mating end 132 and the mounting end 134 cannot be touched by a test finger (which represents a human finger) from every reasonable position.

Thus, the electrical contacts 108 can include first electrical contacts 108 and second electrical connections that are supported by the connector housing 106 and are spaced apart from each other along a lateral direction that is substantially perpendicular to the longitudinal direction L and the lateral direction T, respectively. Point 108. When the first electrical contact 108 and the second electrical contact 108 are mounted to the substrate 104, each of the first electrical contact 108 and the second electrical contact 108 can define at least one mounting terminal that is placed in electrical communication with the substrate 104. 124. Moreover, the connector housing 106 can define electrically insulating fins 156 that can be disposed between the first electrical contact 108 and the second electrical contact 108 along the lateral direction A. Thus, the fins 156 can define a maximum height of the electrical connector 102 along one of the lateral directions T. For example, the bottom end 110d can be spaced from the top end 110c in a direction substantially parallel to one of the lateral directions T, and the mounting terminal 124 can terminate in the downward direction at the mounting end 134 and the fins 156 can terminate in the direction The lower portion is spaced upward from the mounting end 134. Thus, when the electrical connector 102 is mounted to the substrate 104, the fins 156 can extend through the slots 148 in the substrate 104 in a downward direction.

In addition, according to the illustrated embodiment, with reference to FIG. 2D, the mounting portion 120 of each of the first electrical contact 108 and the second electrical contact 108 may terminate in a direction perpendicular to the mating direction M and the lateral direction A. The lateral direction T of each is spaced from the body housing 110 by a first distance d _{1 at} the mounting end 134. The at least one fin 156 can extend from the housing body 110 along the lateral direction T and terminate at a distal end 157 that is spaced apart from the housing body by a second distance d ₂ along the lateral direction T, wherein the second distance d _{2 is} not less than A distance d ₁ . For example, the second distance d ₂ can be greater than the first distance d ₁ . Thus, when the electrical connector 102 is mounted to the substrate 104, the fins 156 can be configured to be inserted into the substrate 104 at least (eg, through the substrate 104) before the mounting portion 120 is inserted into the substrate 104 (eg, through the substrate 104). . Accordingly, the connector housing 106 can define an electrically insulating fin 156 that extends downwardly from the housing body 110 beyond the mounting end 134 along the lateral direction T, and the fin 156 can define a first dimension in the longitudinal direction L and be vertical A second dimension is defined in one of the longitudinal direction L and the lateral direction T in the lateral direction A, and the first dimension may be at least five times larger than the second dimension.

For example, the fins 156 may be longer in the main direction with respect to a primary direction perpendicular to one of the main directions including at least one of the longitudinal direction L and the lateral direction A and not including the lateral direction T. For example, the primary direction can include each of the longitudinal direction L and the lateral direction A. Therefore, the fin 156 can be longer in the other of the longitudinal direction L and the lateral direction A than one of the longitudinal direction L and the lateral direction A. In addition, the fin 156 may define a first dimension on one of the longitudinal direction L and the lateral direction A and a second dimension on the other of the longitudinal direction L and the lateral direction A, and the first size may be It is at least five times larger than the second size. According to the illustrated embodiment, the first dimension is in the longitudinal direction L. Alternatively, it should be understood that the first dimension can be a lateral direction.

Referring to FIG. 6, the fin 156 defines a fin width W ₁ that is less than one of the widths of one of the grooves 148 of the substrate 104 along the lateral direction A such that the groove 148 and thus the substrate 104 can receive the fin 156 such that the fin 156 can Extending through the substrate 104. The plurality of electrical contacts 108 can define a pair of electrical contacts 108 such that each pair of electrical contacts 108 includes a first electrical contact and a second electrical contact, and the second electrical contact is disposed along the lateral direction A. Adjacent to the first electrical contact, the other electrical contacts are not disposed between the first electrical contact and the second electrical contact. Thus, in accordance with the illustrated embodiment, only a single fin 156 can be disposed between each pair of electrical contacts along a lateral direction A. It should be understood that the number of fins disposed between a pair of immediately adjacent electrical contacts 108 can vary as desired. For example, the fins 156 can be disposed along the lateral direction A between the first and second of the electrical contacts, wherein the other of the electrical contacts are not disposed in the immediate direction along the lateral direction A. Between the electrical contacts 108.

Referring to FIGS. 5-6, the substrate 104 can include a plurality of mounting locations 128 that can be provided as plated through holes 126 and slots 148. The plated through holes 126 can be configured to receive the mounting terminals 124 of the electrical contacts 108 as described above. The slot 148 can be configured to receive a portion of the connector housing 106, such as the fins 156. The mounting terminals can define any geometric cross-sectional shape as desired. Additionally, fins 156 can define any geometric cross-sectional shape as desired.

The mounting terminal 124 of the electrical contact 108 defines one of the footprints 130 taken from one of the bottom plan views of one of the electrical connectors 102. The illustrated footprint 130 is depicted as including three electrical contacts 108, although any number of electrical contacts 108 can be provided as desired. The mounting terminals 124 of the electrical contacts 108 are configured in a plurality of rows. For example, the first mounting terminals 124a of the electrical contacts 108 are configured as one of the first rows of the respective contacts 108 (row 1), and the second mounting terminals 124b of the electrical contacts 108 are configured as respective contacts 108. A second line (line 2). Rows 1 and 2 of each electrical contact 108 are laterally disposed adjacent one another and extending in a direction substantially parallel to each other (e.g., longitudinal direction L). Electrical contacts 108 is further configured such that a first electrically row (C ₁₎ of the contact 108 laterally disposed adjacent to the second row adjacent to the electrical contacts 108 (C _2), and a fin 156 is disposed in electrical contact Between the first row (C ₁ ) of point 108 and the second row (C ₂ ) of its adjacent electrical contact 108.

Each electrical contact 108 can define a centerline disposed at a midpoint between the first sidewall 136 and the second sidewall 138 along the lateral direction A. The spacing between the centerlines of adjacent electrical contacts 108 may be referred to as the line spacing CP. The first row and the second row may define a centerline disposed at a midpoint between the first row and the second row along the lateral direction A. The spacing between the centerlines of the midpoints of adjacent rows may be substantially equal to the row spacing CP. In the illustrated embodiment, the line spacing CP can be between 1 mm and 7 mm, such as between 5 mm and 6 mm, such as between, for example, about 5.0 mm or more specifically 5.08 mm. It should be further appreciated that the electrical contacts 108 can be configured And constructed to define any line spacing as desired.

Mounting a first terminal of each of the electrical contacts 124a and the second mounting terminal 108 of one or more up to all of the 124b (in FIG. 5 to FIG. 6 shows) to be disposed with electrical contacts 108 of the column row R ₁ to R ₄ The respective similar terminals 124a and 124b are aligned. Mounting a first or upper position 128 'disposed in a first row (R _1), and a second installation position or under 128 "disposed in a fourth (R _4). According to the embodiment depicted, The groove 148 defines a distance along the longitudinal direction that is greater than the distance between the uppermost surface of the upper mounting position 128' and the lowermost surface of the lower mounting position 128" along the longitudinal direction L. Thus, as depicted, the fins 156 can define a length along the longitudinal direction L that is greater than the distance between one of the mounting terminals in column 1 and one of the mounting terminals in column 4 along the longitudinal direction L. Thus, the fins 156 can be increased by a creepage distance CD as desired (see Figure 6). The fins 156 may increase the creepage distance CD compared to an electrical connector that does not include fins. For example, in one embodiment, the creepage distance CD can be between 4 mm and 8 mm, for example, 4.91 mm. It should be further appreciated that the fins 156 can be constructed to define any creepage distance CD as desired.

Accordingly, the mounting terminals 124a and 124b adjacent to the row 1 and row 2 of the adjacent electrical contacts 108 are separated by a creepage distance greater than the case where there is no slot 148 disposed between them in the lateral direction A. Thus, the connector 102 is shown to provide an increased creepage distance between the mounting terminals without increasing the footprint of the mounting interface of the connector relative to a similarly constructed connector that does not include one of the fins 156. .

It will be further appreciated that the increased creepage distance between the mounting terminals 124a and 124b allows the electrical contact 108 to carry an increased operating voltage (e.g., 400V or greater) relative to conventional terminals while reducing or preventing operation. The arc is mounted across terminals 124a and 124b. The electrical contacts 108 can further carry currents greater than other contacts, and the electrical contacts 108 are configured to be protected from touch.

In other words, the electrical connector 102 can include an electrical housing 106 and a first electrical contact 108. The first electrical contact 108 includes a first mating end 132 and each has a respective first mounting end. A plurality of first mounting terminals 124 of 134. The second electrical contact 108 can be positioned adjacent to the first electrical contact 108. The second electrical contact 108 includes a second mating end 132 and a plurality of second mounting terminals 124 each having a respective second mounting end 134. . The first mounting end 134 of the first mounting terminal 124 can be configured to extend from the substrate 104 and remain exposed, and the second mounting terminal 124 can be configured to extend from the substrate 104 and remain exposed. In addition, as described above, the electrical connector 102 is at the first of the first mating end 132, the second mating end 132, the first mounting end 134 of the first mounting terminal 124, and the second mounting terminal 124. The second mounting end 134 can be touch-proof (for example, the anti-touch of the finger detection program according to IEC 60950). The electrical enclosure 106 can further include an electrically insulating fin 156 positioned between the first mounting terminal 124 and the second mounting terminal 124 and the electrically insulating fin 156 can extend over the first mounting end of the first mounting terminal 124 134 and a second mounting end 134 of the second mounting terminal 124. The electrical enclosure 106 can extend beyond the first mating end 132 of the first electrical contact 108 and the second mating end 132 of the second electrical contact 108.

Referring to Figure 9, an electrical connector 102a includes a signal contact 108a that is configured to transmit data. Signal contact 108a can be protected from touch. In addition, referring to Figures 10A and 10B, it should be understood that the electrical connector 102 can be configured as a neutral electrical connector 102b in accordance with an embodiment. Referring to Figure 10, the neutral electrical connector 102b includes electrical contacts 108b that alternate between a receptacle electrical contact 109a and a plug or plug electrical contact 109b along a lateral direction A such that a substantially balanced edge The mating force of the mating direction M (which can be parallel to the longitudinal direction L). Each of the socket electrical contact 109a and the plug electrical contact 109b is configured to be touch resistant. Additionally, the neutral electrical connector 102b can be configured such that the power contacts do not touch the outer casing 106b of the electrical connector 102b.

In operation, establishing a method of electrically connecting to one of the electrical connectors of one of the following may include transporting the connector housing toward the substrate: 1) a connector housing including a housing body and extending from the housing body a fin that defines a mating interface configured to be mated with a complementary connector housing of a complementary electrical connector and configured to be mounted a mounting interface to a substrate; and 2) a plurality of electrical contacts supported by the connector housing, each of the electrical contacts defining a mounting portion and a mating portion. The fins may be inserted into at least one of the slots in the substrate during the transport step. After the inserting step and during the transporting step, the mounting portion can be inserted into the substrate to place the electrical contacts in electrical communication with the substrate. A relative movement between the electrical connector and the complementary electrical connector can be established along the mating direction to cause the mating portion of the electrical contact to mate with the complementary electrical contact of the complementary electrical connector. The complementary connector housing can be received into a gap extending into the housing body.

In accordance with an embodiment and the above description, a method can include selling a first electrical connector (eg, electrical connector 102) including at least one electrically insulating fin (eg, a plurality of electrically insulating fins 156).

The embodiments described in connection with the illustrated embodiments are presented by way of illustration, and thus the present invention is not intended to be limited to the disclosed embodiments. In addition, the structures and features of the various embodiments described above can be applied to other embodiments described herein unless otherwise indicated. Accordingly, the present invention is intended to cover all modifications and alternatives that are included in the spirit and scope of the present invention as set forth in the accompanying claims.

104‧‧‧First substrate/substrate

124‧‧‧Installation terminal

134‧‧‧Installation end

156‧‧‧Electrically insulated fins

Claims (21)

An electrical connector comprising: a dielectric connector housing including a housing body defining a mounting interface configured to be mounted to a substrate and configured to follow a mating direction At least one complementary electrical connector mating with one of the mating interfaces; a plurality of electrical contacts supported by the connector housing and spaced apart from each other in a lateral direction substantially perpendicular to the mating direction, The isoelectric contact includes: 1) a mating portion configured to mating with a complementary electrical contact of the at least one complementary electrical connector when the connector housing mates with the at least one complementary electrical connector And 2) a mounting portion configured to be electrically connected to the substrate when the connector housing is mounted to the substrate; at least one electrically insulating fin supported by the housing body, the at least one fin Disposed between the at least first electrical contact and the second electrical contact of the plurality of electrical contacts along the lateral direction, wherein: 1) each of the first electrical contact and the second electrical contact The mounting portion may terminate in each of a direction perpendicular to the mating direction and the lateral direction The transverse direction is spaced from the outer casing body by a first distance from the mounting end; 2) the at least one fin extends from the outer casing body along the lateral direction and terminates in a second space along the lateral direction from the outer casing body One of the distances is distal; and 3) the second distance is not less than the first distance. The electrical connector of claim 1, wherein the second distance is greater than the first distance. The electrical connector of claim 2, wherein the at least one fin is configured to be inserted into the substrate at least before the mounting portion is inserted into the substrate, the electrical connector being mounted to the substrate. The electrical connector of claim 1, wherein the matching direction is perpendicular to the inclusion One of the lateral directions is in a main direction and does not include a primary direction of the lateral direction, and the at least one fin is longer in the main direction. The electrical connector of claim 4, wherein the primary direction comprises each of the mating direction and the lateral direction. The electrical connector of claim 1, wherein the at least one fin is longer in the mating direction and the other of the lateral directions than the one of the mating direction and the lateral direction. The electrical connector of claim 6, wherein the at least one fin defines a first dimension in one of the mating direction and the lateral direction and is on the other of the mating direction and the lateral direction A second dimension is defined, and the first dimension is at least five times greater than the second dimension. The electrical connector of claim 7, wherein the first dimension is in the mating direction. The electrical connector of claim 7, wherein the first dimension is in the lateral direction. The electrical connector of claim 1, wherein the at least one fin is integral with the housing body. The electrical connector of claim 1, wherein the at least one fin is attached to the housing body. The electrical connector of claim 1, the electrical connector further comprising at least one electrically insulating arm supported by the outer casing body, the at least one arm extending beyond the mating portions in the mating direction such that the mating A portion terminates in the mating direction at a position inwardly disposed relative to a position at which the arm terminates in the mating direction. The electrical connector of claim 1, wherein the plurality of electrical contacts define a pair of electrical contacts, each pair of electrical contacts comprising a first electrical contact and a second electrical contact, the second electrical contact being disposed Adjacent to the first electrical contact such that other electrical contacts are not disposed between the first electrical contact and the second electrical contact. The electrical connector of claim 13, wherein a single fin is disposed between each pair of electrical contacts along the lateral direction. The electrical connector of claim 1, wherein each of the electrical contacts comprises: 1) a first sidewall and a second sidewall spaced apart from each other along the lateral direction to define a first distance; 2) a first plurality of mounting terminals and a second plurality of mounting terminals spaced apart from each other along the lateral direction to define a second distance less than the first distance; 3) a first neck, wherein the first A sidewall extends between the first plurality of mounting terminals; and 4) a second neck extending between the second sidewall and the second plurality of mounting terminals. The electrical connector of claim 1, wherein the electrical connector is a power connector. An electrical connector configured to mate with at least one complementary electrical connector and further configured to be mounted to a substrate along a mounting direction, the electrical connector comprising: an electrically insulative connector housing including a housing body defining a front end, a rear end opposite the front end along a longitudinal direction, a top end extending from the front end to a rear end, and a transverse direction perpendicular to the longitudinal direction a bottom end of the top end, the bottom end defining a mounting interface configured to be mounted to the substrate; a plurality of electrical contacts supported by the connector housing, each of the electrical contacts Defining at least one mounting end extending downwardly from the connector housing along the lateral direction, wherein 1) the connector housing defines an electrically insulating fin extending downwardly from the housing body in the lateral direction beyond the mounting ends And (2) the fin defines a first dimension in the longitudinal direction and defines a second dimension in a lateral direction perpendicular to the longitudinal direction and the lateral direction, and the first dimension is The second size At least five times larger. The electrical connector of claim 17, wherein the fin is disposed along the lateral direction between the first one and the second of the electrical contacts, and the other of the electrical contacts are not along the side The direction is disposed between the immediately adjacent electrical contacts. The electrical connector of claim 17, wherein the connector housing includes an inner surface defining at least one opening such that at least one of the plurality of electrical contacts is disposed in the opening, the inner surface at least substantially surrounding The at least one of the plurality of electrical contacts, and the inner surface extends from the housing body along the mating direction beyond one of the at least one of the plurality of electrical contacts, the isoelectric The at least one of the contacts terminates at the mating end. The electrical connector of claim 19, wherein the bottom end is spaced from the top end in a downward direction along one of the lateral directions, and wherein the electrical contact terminates further along the downward direction at the mounting end and the fin Terminate at a position spaced from the mounting end in the downward direction. The electrical connector of claim 17, wherein the fin extends through the slot in the substrate in the downward direction when the electrical connector is mounted to the substrate.